# On maximal multiplicities for Hamiltonians with separable variables

**Authors:** B. Helffer, T. Hoffmann-Ostenhof, and P. Marquetand

arXiv: 1908.02752 · 2019-08-09

## TL;DR

This paper investigates the maximum possible multiplicities of eigenvalues for Hamiltonians with separable variables, providing exact results for two and three dimensions and exploring the complexity of the problem in higher dimensions.

## Contribution

The paper derives exact maximum multiplicities for N=2, 3 and offers lower bounds and conjectures for general N, advancing understanding of eigenvalue multiplicities in separable Hamiltonian systems.

## Key findings

- Exact maximum multiplicity for N=2
- Exact maximum multiplicity for N=3
- Lower bounds and conjectures for general N

## Abstract

For $\mathbb N^*:=\mathbb N \setminus \{0\}$, we consider the collection $\mathfrak M(N)$ of all the $N$ rows, for which, for $n=1,\cdots,N$, the $n-th$ row consists of an increasing sequence $(a_j^n)_j$ of real numbers. For $\mathfrak A \in \mathfrak M(N)$, we define its spectrum $\sigma(\mathfrak A)$ by $\sigma(\mathfrak A)=\{\lambda\in \mathbb R \;|\; \lambda=\sum_{n=1}^Na_{j_n}^n\}\,,$ where $(j_1,j_2,\dots,j_N)\in (\mathbb N^*)^N$. This spectrum is discrete and consists of an infinite sequence that can be ordered as a strictly increasing sequence $\lambda_k(\mathfrak A)$. For $\lambda \in \sigma (\mathfrak A)$ we denote by $m(\lambda,\mathfrak A) $ the number of representations of such a $\lambda$, hence the multiplicity of $\lambda$.\\ In this paper we investigate for given $N\in \mathbb N^*$ and $k\in \mathbb N^*$ the highest possible multiplicity (denoted by $\mathfrak m_k(N)$) of $\lambda_k(\mathfrak A)$ for $\mathfrak A \in \mathfrak M(N)$. We give the exact result for $N=2$ and for $N=3$ prove a lower bound which appears, according to numerical experiments, as a "good" conjecture. For the general case, we give examples demonstrating that the problem is quite difficult. \\ This problem is equivalent to the analogue eigenvalue multiplicity questions for Schr\"odinger operators describing a system of N non-interacting one-dimensional particles.

## Full text

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## References

6 references — full list in the complete paper: https://tomesphere.com/paper/1908.02752/full.md

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Source: https://tomesphere.com/paper/1908.02752